A falling star is really a Meteor and is a form of space debris. They are not really stars at all. There are cases where meteors have entered the Earth’s atmosphere. In most cases, Meteors burn up upon entry into the atmosphere and never make it to the surface of the planet. There are times when the meteor starts to burn up, but because the mass is big enough, it makes it to the surface, smaller then when it started out. Through both means, the meteor deals with some measure of resistance upon entering the atmosphere. The main resistance that the meteor encounters is air resistance (or drag). Due to this collision with the atmosphere, the meteor’s surface begins to melt and vaporize causing the meteor to start breaking apart at its outer layers.
When a meteor enters Earth’s atmosphere, they enter at a minimum velocity. This minimum velocity is about 11km per second (25,000 miles per hour). That is quicker then a bullet being fired from a gun. That is only the minimum; there are meteors that can get going much faster. Another comparison to this is that a space shuttle moves around the Earth roughly at about 8km per second.
Most meteors burn up when they enter Earth’s atmosphere. There are a few meteors however, that make it to the surface. The ones that make it to the ground are called meteorites.
Not all meteors are the same material wise. Some meteors are made out of rock, while others are made out of iron. Some even have a mixture of both, but in most cases, it is one or the other.
A fun fact that came up is that as much a 4 billion meteors fall to the Earth each day. Most of them are not significant enough for anyone to notice. Another one is that the Earth gains about a million kilograms of mass a day from meteors.
If you let N equal the number of stone meteorites, which fall on one km2 of the surface of the Earth during a one-year period and N, includes all meteorites with a mass greater then or equal to m kg. The rate of the number of meteorites that touches down is:
17. The diagram to the right illustrates what type of geologic event? Explain. (S6E5e, f)
Shown in the picture above is volcanic extrusive igneous rock known as andesite. They were imported here to Laguna Beach to help minimize erosion (Merton Hill, p. 10-11). Extrusive Igneous rocks are formed on Earths surface due to lava quickly cooling or mixing with different materials such as ash or cinders from an eruption. There are two different types of extrusive igneous rocks; Plutonic and Volcanic. Andesite is known for being gray in color and being made up of very coarse grainy textures, which make it much harder to break down than sedimentary rocks. Unlike loose gravel and other sediments igneous rocks are known for being able to slow down seismic waves from earthquakes which cause less damage to surface structures.
If the star is big enough and the pressure inside quickly disappears, gravity would and should slingshot the star into a tiny point with near infinite density with an extremely strong gravitatio... ... middle of paper ... ...is its anti particle. When these particles appear, they will shortly annihilate each other because they are exact opposites (UCR). However, if one of these particle pairs appears at the event horizon of a black hole, the gravity from the black hole will tear the pair of particles apart. The normal particle will have just enough energy to escape the black hole.
However, asteroids are much more deadly. If over-sized meteor can wreck buildings and injure people, then a normal sized asteroid can easily wipe out species if it lands in the right place. As mentioned before, asteroids are much bigger than meteor and much more rare. According to the “Mail Online” 12,000 years ago some type of asteroid slammed into the Northern Canada and some scientist believe that wiped off the mammoths and caused the “Younger Dryas”. Another famous event of asteroids striking, that many scientist believe, was around 65 million years ago asteroids rained and killed of all the dinosaurs 75% of all the life on earth.
Avalanches kill back country recreationalists every year, including skiers, snowboarders, snowshoers, and snowmachiners. All back country users should have knowledge of the basic physics of avalanches to help them evaluate local and regional potential for slides. The foundation of this knowledge comes from understanding how the surrounding environmental conditions in previous weeks, previous days, and the day in question all contribute to snow stability or instability, and how specific factors affect snow on a micro-scale, which determines how snow slopes will behave on a macro-scale. There are two major types of avalanches (excluding debris avalanches from broken cornices and ice formations). These are point releases, or loose snow slides, and slab avalanches. While point releases can be dangerous and should be avoided, slab avalanches are much more catastrophic and account for most of the backcountry avalanche disasters involving humans. Basic physics of point releases are discussed here, followed by a discussion on the basic physics of slab avalanches, and how external factors contribute to the stability or instability of a snow covered slope.
Armageddon begins by showing the destruction of the Earth by an asteroid 65 million years ago, when the dinosaurs inhabited the earth. According to the narration, the asteroid is said to have been six miles wide, with the power of 10,000 nuclear weapons. The after effects were trillions of tons of dirt and rock thrown into the atmosphere, creating a blanket of dust that the sun was unable to penetrate for 1,000 years. The narrator explained that it happened once, and that it would happen again, it was only a matter of when.
Stars are born and reborn from an explosion of a previous star. The particles and helium are brought together the same way the last star was born. Throughout the life of a star, it manages to avoid collapsing. The gravitational pull from the core of the star has to equal the gravitational pull of the gasses, which form a type of orbit. When this equality is broken, the star can go into several different stages. Some stars that are at least thirty times larger than our sun can form black holes and other kinds of stars.
An object that is falling through the atmosphere is subjected to two external forces. The first force is the gravitational force, expressed as the weight of the object. The weight equation which is weight (W) = mass (M) x gravitational acceleration (A) which is 9.8 meters per square second on the surface of the earth. The gravitational acceleration decreases with the square of the distance from the center of the earth. If the object were falling in a vacuum, this would be the only force acting on the object. But in the atmosphere, the motion of a falling object is opposed by the air resistance or drag. The drag equation tells us that drag is equal to a coefficient times one half the air density (R) times the velocity (V) squared times a reference area on which the drag coefficient is based.
Sixty-Five million years ago, 70 percent of life on Earth died. The most reasonable and possible reason this happened was an asteroid. An asteroid hit the Earth very hard, and in doing this, dirt and dust from the impact stayed in the air and it blocked out sunlight, that’s why the dinosaurs died. An asteroid is a rock from outer space. Asteroids have orbited the Sun along with the planets since the solar system formed about 4.6 billion years ago, but it’s only been 200 years since we first discovered them. Meteorites are small pieces of asteroids broken off on impact with other asteroids. Most meteorites are rusty brown on the outside, have rounded edges from melting as they go through Earth’s atmosphere, and contain iron. There are 3 different types of meteorites: stony, metallic, and stony metallic.92 percents of all asteroids are stone, 6 percent are made of iron and nickel, and the rest are a combination. Some meteorites also contain gold, copper, platinum, and carbon.
William, Armstrong. “Colliding Bodies.” The Washington Times Aug. 11, 2001. Academic Universe. Lexis Nexis. EBSCO Publishing. Colorado State University Lib. Mar. 2003 http://lib.colostate.edu/databases/>
comes up in a crack in the Earth’s crust, it does not come to the surface, but
Comets are made up of four distinct features. The first is the nucleus. The nucleus is made up of frozen gases, mostly water vapor with lesser amounts of carbon dioxide and carbon monoxide, and imbedded in the frozen gases are interplanetary dust and tiny fragments of stony and metallic meteoric material. Some comets, the larger ones, have a nucleus of 10 kilometers (Schweighauser 22).
Igneous rocks are formed from the ejection of earth’s volcanoes. Deep down inside earth’s mantle there lies hot magma. Magma is molten rock that is kept below the surface. This mixture is usually made up of four parts: a hot liquid substance which is called the melt; minerals that have been crystallized by the melt; solid rocks that have made themselves tangled in the melt because of loose materials, and finally gases that have become liquid. Magma is created by an increase in temperatures, pressure change, and a alter in composition. When this magma is ejected from earth’s crust it earns a new name called lava. The lava hardens and becomes an Igneous rock.
There are more than 20,000 pieces of debris larger than a softball orbiting the Earth. This debris can travel at speeds up to 17,500 mph. Even a relatively small piece of space debris can damage a satellite or a spacecraft at these speeds. Additionally, there are more than 500,000 pieces...
These miscellaneous pieces, ranging from the size of a marble to a softball, travel at speeds up to 17,500 mph. The rising population of space debris increases the foreseen danger to all space vehicles, but especially to the International Space Station, space shuttles and other spacecraft with humans aboard (NASA, 2012).